DockerCLI/vendor/google.golang.org/grpc/internal/channelz/channelmap.go

396 lines
10 KiB
Go

/*
*
* Copyright 2018 gRPC authors.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*/
package channelz
import (
"fmt"
"sort"
"sync"
"time"
)
// entry represents a node in the channelz database.
type entry interface {
// addChild adds a child e, whose channelz id is id to child list
addChild(id int64, e entry)
// deleteChild deletes a child with channelz id to be id from child list
deleteChild(id int64)
// triggerDelete tries to delete self from channelz database. However, if
// child list is not empty, then deletion from the database is on hold until
// the last child is deleted from database.
triggerDelete()
// deleteSelfIfReady check whether triggerDelete() has been called before,
// and whether child list is now empty. If both conditions are met, then
// delete self from database.
deleteSelfIfReady()
// getParentID returns parent ID of the entry. 0 value parent ID means no parent.
getParentID() int64
Entity
}
// channelMap is the storage data structure for channelz.
//
// Methods of channelMap can be divided into two categories with respect to
// locking.
//
// 1. Methods acquire the global lock.
// 2. Methods that can only be called when global lock is held.
//
// A second type of method need always to be called inside a first type of method.
type channelMap struct {
mu sync.RWMutex
topLevelChannels map[int64]struct{}
channels map[int64]*Channel
subChannels map[int64]*SubChannel
sockets map[int64]*Socket
servers map[int64]*Server
}
func newChannelMap() *channelMap {
return &channelMap{
topLevelChannels: make(map[int64]struct{}),
channels: make(map[int64]*Channel),
subChannels: make(map[int64]*SubChannel),
sockets: make(map[int64]*Socket),
servers: make(map[int64]*Server),
}
}
func (c *channelMap) addServer(id int64, s *Server) {
c.mu.Lock()
defer c.mu.Unlock()
s.cm = c
c.servers[id] = s
}
func (c *channelMap) addChannel(id int64, cn *Channel, isTopChannel bool, pid int64) {
c.mu.Lock()
defer c.mu.Unlock()
cn.trace.cm = c
c.channels[id] = cn
if isTopChannel {
c.topLevelChannels[id] = struct{}{}
} else if p := c.channels[pid]; p != nil {
p.addChild(id, cn)
} else {
logger.Infof("channel %d references invalid parent ID %d", id, pid)
}
}
func (c *channelMap) addSubChannel(id int64, sc *SubChannel, pid int64) {
c.mu.Lock()
defer c.mu.Unlock()
sc.trace.cm = c
c.subChannels[id] = sc
if p := c.channels[pid]; p != nil {
p.addChild(id, sc)
} else {
logger.Infof("subchannel %d references invalid parent ID %d", id, pid)
}
}
func (c *channelMap) addSocket(s *Socket) {
c.mu.Lock()
defer c.mu.Unlock()
s.cm = c
c.sockets[s.ID] = s
if s.Parent == nil {
logger.Infof("normal socket %d has no parent", s.ID)
}
s.Parent.(entry).addChild(s.ID, s)
}
// removeEntry triggers the removal of an entry, which may not indeed delete the
// entry, if it has to wait on the deletion of its children and until no other
// entity's channel trace references it. It may lead to a chain of entry
// deletion. For example, deleting the last socket of a gracefully shutting down
// server will lead to the server being also deleted.
func (c *channelMap) removeEntry(id int64) {
c.mu.Lock()
defer c.mu.Unlock()
c.findEntry(id).triggerDelete()
}
// tracedChannel represents tracing operations which are present on both
// channels and subChannels.
type tracedChannel interface {
getChannelTrace() *ChannelTrace
incrTraceRefCount()
decrTraceRefCount()
getRefName() string
}
// c.mu must be held by the caller
func (c *channelMap) decrTraceRefCount(id int64) {
e := c.findEntry(id)
if v, ok := e.(tracedChannel); ok {
v.decrTraceRefCount()
e.deleteSelfIfReady()
}
}
// c.mu must be held by the caller.
func (c *channelMap) findEntry(id int64) entry {
if v, ok := c.channels[id]; ok {
return v
}
if v, ok := c.subChannels[id]; ok {
return v
}
if v, ok := c.servers[id]; ok {
return v
}
if v, ok := c.sockets[id]; ok {
return v
}
return &dummyEntry{idNotFound: id}
}
// c.mu must be held by the caller
//
// deleteEntry deletes an entry from the channelMap. Before calling this method,
// caller must check this entry is ready to be deleted, i.e removeEntry() has
// been called on it, and no children still exist.
func (c *channelMap) deleteEntry(id int64) entry {
if v, ok := c.sockets[id]; ok {
delete(c.sockets, id)
return v
}
if v, ok := c.subChannels[id]; ok {
delete(c.subChannels, id)
return v
}
if v, ok := c.channels[id]; ok {
delete(c.channels, id)
delete(c.topLevelChannels, id)
return v
}
if v, ok := c.servers[id]; ok {
delete(c.servers, id)
return v
}
return &dummyEntry{idNotFound: id}
}
func (c *channelMap) traceEvent(id int64, desc *TraceEvent) {
c.mu.Lock()
defer c.mu.Unlock()
child := c.findEntry(id)
childTC, ok := child.(tracedChannel)
if !ok {
return
}
childTC.getChannelTrace().append(&traceEvent{Desc: desc.Desc, Severity: desc.Severity, Timestamp: time.Now()})
if desc.Parent != nil {
parent := c.findEntry(child.getParentID())
var chanType RefChannelType
switch child.(type) {
case *Channel:
chanType = RefChannel
case *SubChannel:
chanType = RefSubChannel
}
if parentTC, ok := parent.(tracedChannel); ok {
parentTC.getChannelTrace().append(&traceEvent{
Desc: desc.Parent.Desc,
Severity: desc.Parent.Severity,
Timestamp: time.Now(),
RefID: id,
RefName: childTC.getRefName(),
RefType: chanType,
})
childTC.incrTraceRefCount()
}
}
}
type int64Slice []int64
func (s int64Slice) Len() int { return len(s) }
func (s int64Slice) Swap(i, j int) { s[i], s[j] = s[j], s[i] }
func (s int64Slice) Less(i, j int) bool { return s[i] < s[j] }
func copyMap(m map[int64]string) map[int64]string {
n := make(map[int64]string)
for k, v := range m {
n[k] = v
}
return n
}
func (c *channelMap) getTopChannels(id int64, maxResults int) ([]*Channel, bool) {
if maxResults <= 0 {
maxResults = EntriesPerPage
}
c.mu.RLock()
defer c.mu.RUnlock()
l := int64(len(c.topLevelChannels))
ids := make([]int64, 0, l)
for k := range c.topLevelChannels {
ids = append(ids, k)
}
sort.Sort(int64Slice(ids))
idx := sort.Search(len(ids), func(i int) bool { return ids[i] >= id })
end := true
var t []*Channel
for _, v := range ids[idx:] {
if len(t) == maxResults {
end = false
break
}
if cn, ok := c.channels[v]; ok {
t = append(t, cn)
}
}
return t, end
}
func (c *channelMap) getServers(id int64, maxResults int) ([]*Server, bool) {
if maxResults <= 0 {
maxResults = EntriesPerPage
}
c.mu.RLock()
defer c.mu.RUnlock()
ids := make([]int64, 0, len(c.servers))
for k := range c.servers {
ids = append(ids, k)
}
sort.Sort(int64Slice(ids))
idx := sort.Search(len(ids), func(i int) bool { return ids[i] >= id })
end := true
var s []*Server
for _, v := range ids[idx:] {
if len(s) == maxResults {
end = false
break
}
if svr, ok := c.servers[v]; ok {
s = append(s, svr)
}
}
return s, end
}
func (c *channelMap) getServerSockets(id int64, startID int64, maxResults int) ([]*Socket, bool) {
if maxResults <= 0 {
maxResults = EntriesPerPage
}
c.mu.RLock()
defer c.mu.RUnlock()
svr, ok := c.servers[id]
if !ok {
// server with id doesn't exist.
return nil, true
}
svrskts := svr.sockets
ids := make([]int64, 0, len(svrskts))
sks := make([]*Socket, 0, min(len(svrskts), maxResults))
for k := range svrskts {
ids = append(ids, k)
}
sort.Sort(int64Slice(ids))
idx := sort.Search(len(ids), func(i int) bool { return ids[i] >= startID })
end := true
for _, v := range ids[idx:] {
if len(sks) == maxResults {
end = false
break
}
if ns, ok := c.sockets[v]; ok {
sks = append(sks, ns)
}
}
return sks, end
}
func (c *channelMap) getChannel(id int64) *Channel {
c.mu.RLock()
defer c.mu.RUnlock()
return c.channels[id]
}
func (c *channelMap) getSubChannel(id int64) *SubChannel {
c.mu.RLock()
defer c.mu.RUnlock()
return c.subChannels[id]
}
func (c *channelMap) getSocket(id int64) *Socket {
c.mu.RLock()
defer c.mu.RUnlock()
return c.sockets[id]
}
func (c *channelMap) getServer(id int64) *Server {
c.mu.RLock()
defer c.mu.RUnlock()
return c.servers[id]
}
type dummyEntry struct {
// dummyEntry is a fake entry to handle entry not found case.
idNotFound int64
Entity
}
func (d *dummyEntry) String() string {
return fmt.Sprintf("non-existent entity #%d", d.idNotFound)
}
func (d *dummyEntry) ID() int64 { return d.idNotFound }
func (d *dummyEntry) addChild(id int64, e entry) {
// Note: It is possible for a normal program to reach here under race
// condition. For example, there could be a race between ClientConn.Close()
// info being propagated to addrConn and http2Client. ClientConn.Close()
// cancel the context and result in http2Client to error. The error info is
// then caught by transport monitor and before addrConn.tearDown() is called
// in side ClientConn.Close(). Therefore, the addrConn will create a new
// transport. And when registering the new transport in channelz, its parent
// addrConn could have already been torn down and deleted from channelz
// tracking, and thus reach the code here.
logger.Infof("attempt to add child of type %T with id %d to a parent (id=%d) that doesn't currently exist", e, id, d.idNotFound)
}
func (d *dummyEntry) deleteChild(id int64) {
// It is possible for a normal program to reach here under race condition.
// Refer to the example described in addChild().
logger.Infof("attempt to delete child with id %d from a parent (id=%d) that doesn't currently exist", id, d.idNotFound)
}
func (d *dummyEntry) triggerDelete() {
logger.Warningf("attempt to delete an entry (id=%d) that doesn't currently exist", d.idNotFound)
}
func (*dummyEntry) deleteSelfIfReady() {
// code should not reach here. deleteSelfIfReady is always called on an existing entry.
}
func (*dummyEntry) getParentID() int64 {
return 0
}
// Entity is implemented by all channelz types.
type Entity interface {
isEntity()
fmt.Stringer
id() int64
}